Updating examples

2018-08-08 18:49:56 -07:00 · 2018-08-08 18:49:56 -07:00 · 88efafa0e2
parent 3457f11211
commit 88efafa0e2
23 changed files with 1 additions and 28603 deletions
--- a/examples/AFSK_PacketTester/AFSK_PacketTester.ino
+++ b/examples/AFSK_PacketTester/AFSK_PacketTester.ino
@ -1,127 +0,0 @@
 /* Hamshield
 * Example: AFSK Packet Tester
 * This example sends AFSK test data. You will need a seperate 
 * AFSK receiver to test the output of this example.
 * Connect the HamShield to your Arduino. Screw the antenna 
 * into the HamShield RF jack. Connect the Arduino to wall 
 * power and then to your computer via USB. After uploading 
 * this program to your Arduino, open the Serial Monitor to 
 * monitor the process of the HamShield. Check for output on 
 * AFSK receiver.
 *  Note: add message receive code
 */
 #define DDS_REFCLK_DEFAULT 9600
 #include <HamShield.h>
 #include <DDS.h>
 #include <packet.h>
 #include <avr/wdt.h> 
 #define PWM_PIN 3
 #define RESET_PIN A3
 #define SWITCH_PIN 2
 HamShield radio;
 DDS dds;
 AFSK afsk;
 String messagebuff = "";
 String origin_call = "";
 String destination_call = "";
 String textmessage = "";
 int msgptr = 0;
 void setup() {
  // NOTE: if not using PWM out, it should be held low to avoid tx noise
  pinMode(PWM_PIN, OUTPUT);
  digitalWrite(PWM_PIN, LOW);
  // prep the switch
  pinMode(SWITCH_PIN, INPUT_PULLUP);
  // set up the reset control pin
  pinMode(RESET_PIN, OUTPUT);
  // turn on pwr to the radio
  digitalWrite(RESET_PIN, HIGH);
  delay(5); // wait for device to come up
  Serial.begin(9600);
  radio.initialize();
  radio.frequency(144390);
  radio.setRfPower(0);
  // radio.bypassPreDeEmph();
  dds.start();
  afsk.start(&dds);
  delay(100);
  Serial.println("HELLO");
 }
 void loop() {
  prepMessage();
  delay(10000);
 } 
 void prepMessage() { 
  radio.setModeTransmit();
  delay(500);
  origin_call = "KC7IBT"; // get originating callsign
  destination_call = "KC7IBT"; // get the destination call
  textmessage = ":HAMSHIELD TEST";
  Serial.print("From: "); Serial.print(origin_call); Serial.print(" To: "); Serial.println(destination_call); Serial.println("Text: "); Serial.print(textmessage);
  AFSK::Packet *packet = AFSK::PacketBuffer::makePacket(22 + 32);
  packet->start();
  packet->appendCallsign(destination_call.c_str(),0);
  packet->appendCallsign(origin_call.c_str(),15,true);   
  packet->appendFCS(0x03);
  packet->appendFCS(0xf0);
  packet->print(textmessage);
  packet->finish();
  bool ret = afsk.putTXPacket(packet);
  if(afsk.txReady()) {
    Serial.println(F("TX"));
    radio.setModeTransmit();
    //delay(100);
    if(afsk.txStart()) {
    } else {
      radio.setModeReceive();
    }
  }
  // Wait 2 seconds before we send our beacon again.
  // Wait up to 2.5 seconds to finish sending, and stop transmitter.
  // TODO: This is hackery.
  for(int i = 0; i < 500; i++) {
    if(afsk.encoder.isDone())
       break;
    delay(50);
  }
  Serial.println("RX");
  radio.setModeReceive();
 }
 ISR(TIMER2_OVF_vect) {
  TIFR2 = _BV(TOV2);
  static uint8_t tcnt = 0;
  if(++tcnt == 8) {
    dds.clockTick();
    tcnt = 0;
  }
 }
 ISR(ADC_vect) {
  static uint8_t tcnt = 0;
  TIFR1 = _BV(ICF1); // Clear the timer flag
  dds.clockTick();
  if(++tcnt == 1) {
    if(afsk.encoder.isSending()) {
      afsk.timer();
    }
    tcnt = 0;
  }
 }
--- a/examples/APRSMessenger/background.js
+++ b/examples/APRSMessenger/background.js
@ -1,13 +0,0 @@
 chrome.app.runtime.onLaunched.addListener(function() {
  chrome.app.window.create("window.html", {
    "bounds": {
        "width": 685,
        "height": 800
    }
    });
 });
  $(function() {
    $( "#tabs" ).tabs();
  });
--- a/examples/APRSMessenger/bars-0.png
+++ b/examples/APRSMessenger/bars-0.png
--- a/examples/APRSMessenger/bars-1.png
+++ b/examples/APRSMessenger/bars-1.png
--- a/examples/APRSMessenger/bars-2.png
+++ b/examples/APRSMessenger/bars-2.png
--- a/examples/APRSMessenger/bars-3.png
+++ b/examples/APRSMessenger/bars-3.png
--- a/examples/APRSMessenger/jquery-1.10.2.js
+++ b/examples/APRSMessenger/jquery-1.10.2.js
--- a/examples/APRSMessenger/jquery-ui.css
+++ b/examples/APRSMessenger/jquery-ui.css
--- a/examples/APRSMessenger/jquery-ui.js
+++ b/examples/APRSMessenger/jquery-ui.js
--- a/examples/APRSMessenger/manifest.json
+++ b/examples/APRSMessenger/manifest.json
@ -1,10 +0,0 @@
 {
  "name": "HamShield",
  "description": "HamShield",
  "version": "1.0.0",
  "app": {
    "background": {
        "scripts": ["background.js"]
    }
  }
 }
--- a/examples/APRSMessenger/project.ps
+++ b/examples/APRSMessenger/project.ps
@ -1 +0,0 @@
 chromeApp
--- a/examples/APRSMessenger/styles.css
+++ b/examples/APRSMessenger/styles.css
@ -1,48 +0,0 @@
 body{
  display: inline-block;  
 }
 .btn {
  background: #adadad;
  background-image: -webkit-linear-gradient(top, #adadad, #3d3d3d);
  background-image: -moz-linear-gradient(top, #adadad, #3d3d3d);
  background-image: -ms-linear-gradient(top, #adadad, #3d3d3d);
  background-image: -o-linear-gradient(top, #adadad, #3d3d3d);
  background-image: linear-gradient(to bottom, #adadad, #3d3d3d);
  -webkit-border-radius: 0;
  -moz-border-radius: 0;
  border-radius: 0px;
  font-family: Arial;
  color: #ffffff;
  font-size: 20px;
  padding: 10px 20px 10px 20px;
  text-decoration: none;
  float: left;
  text-align:center;
 }
 .btn:hover {
  background: #3d3d3d;
  text-decoration: none;
 }
 .lcd {
  -webkit-border-radius: 0;
  -moz-border-radius: 0;
  border-radius: 0px;
  font-family: Courier New;
  color: #00ff00;
  font-size: 50px;
  background: #000000;
  padding: 10px 20px 10px 20px;
  text-decoration: none;
  width: 500px;
 }
 .lcd:hover {
  text-decoration: none;
 }
 .bs1 { width: 50px; }
 .bs2 { width: 100px; }
 .bs3 { width: 200px; }
--- a/examples/APRSMessenger/window.html
+++ b/examples/APRSMessenger/window.html
@ -1,61 +0,0 @@
 <!DOCTYPE html>
 <html lang="en">
  <head>
    <link rel="stylesheet" type="text/css" href="styles.css">
  <meta charset="utf-8">
  <title>APRSMessenger</title>
  <link rel="stylesheet" href="jquery-ui.css">
  <script src="jquery-1.10.2.js"></script>
  <script src="jquery-ui.js"></script>
 </head>
  <body>
    <div class="lcd" style="width: 768px">
       144.390 MHz | APRS | <img src="bars-3.png" style="height: 32px; width: 32px;">
    </div>
    <div class="lcd" style="width: 768px; font-size: 15px;">
      2M | BW: 25KHz | TX CTCSS: OFF | RX CTCSS: OFF | Filter: OFF | Presence: Available 
    </div>
    <div class="btn" style="width: 75px">
       Tune
    </div>
    <div class="btn">
       Presence
    </div>
    <div class="btn">
      GPS
    </div>
    <div class="btn">
      SSTV
    </div>
    <div class="btn">
      WX
    </div>
    <div class="btn">
      MSG
    </div>
    <div class="btn">
      SQ-
    </div>
    <div class="btn">
      SQ+
    </div>
    <div class="btn">
      VOL
    </div>
    <br/><br/>
    <div id="tabs">
     <ul>
       <li><a href="#tabs-1">Console</a></li>
       <li><a href="#tabs-2">KG7OGM</a></li>
       <li><a href="#tabs-3">KC7IBT</a></li>
     </ul>
    </div>
    <div id="tabs-1">
      Debug messages
    </div>
    <div id="tabs-2">
    </div>
    <div id="tabs-3">
    </div>
  </body>
 </html>
--- a/examples/AX25Receive/AX25Receive.ino
+++ b/examples/AX25Receive/AX25Receive.ino
@ -1,94 +0,0 @@
 /* Hamshield
 * Example: AX25 Receive
 * This example receives AFSK test data. You will need seperate 
 * AFSK equipment to send data for this example.
 * Connect the HamShield to your Arduino. Screw the antenna 
 * into the HamShield RF jack. Plug a pair of headphones into 
 * the HamShield. Connect the Arduino to wall power and then to 
 * your computer via USB. After uploading this program to your 
 * Arduino, open the Serial Monitor so you will see the AFSK 
 * packet. Send AFSK packet from AFSK equipment at 145.01MHz.
 *  Note: add message receive code
 */
 #include <HamShield.h>
 #include <DDS.h>
 #include <packet.h>
 #define PWM_PIN 3
 #define RESET_PIN A3
 #define SWITCH_PIN 2
 HamShield radio;
 DDS dds;
 AFSK afsk;
 void setup() {
  // NOTE: if not using PWM out, it should be held low to avoid tx noise
  pinMode(PWM_PIN, OUTPUT);
  digitalWrite(PWM_PIN, LOW);
  // prep the switch
  pinMode(SWITCH_PIN, INPUT_PULLUP);
  // set up the reset control pin
  pinMode(RESET_PIN, OUTPUT);
  // turn on radio
  digitalWrite(RESET_PIN, HIGH);
  delay(5); // wait for device to come up
  Serial.begin(9600);
  Serial.println(F("Radio test connection"));
  Serial.println(radio.testConnection(), DEC);
  Serial.println(F("Initialize"));
  delay(100);
  radio.initialize();
  radio.frequency(145010);
  radio.setSQOff();
  Serial.println(F("Frequency"));
  Serial.println(radio.getFrequency());
  delay(100);
  Serial.print(F("Squelch(H/L): "));
  Serial.print(radio.getSQHiThresh());
  Serial.print(F(" / "));
  Serial.println(radio.getSQLoThresh());
  radio.setModeReceive();
  //radio.bypassPreDeEmph();
  Serial.println(F("DDS Start"));
  delay(100);
  dds.start();
  Serial.println(F("AFSK start"));
  delay(100);
  afsk.start(&dds);
  Serial.println(F("Starting..."));
  delay(100);
  dds.setAmplitude(255);
 }
 uint32_t last = 0;
 void loop() {
   if(afsk.decoder.read() || afsk.rxPacketCount()) {
      // A true return means something was put onto the packet FIFO
      // If we actually have data packets in the buffer, process them all now
      while(afsk.rxPacketCount()) {
        AFSK::Packet *packet = afsk.getRXPacket();
        Serial.print(F("Packet: "));
        if(packet) {
          packet->printPacket(&Serial);
          AFSK::PacketBuffer::freePacket(packet);
        }
      }
    }
 }
 //TODO: d2 is the switch input, so remove this
 ISR(ADC_vect) {
  static uint8_t tcnt = 0;
  TIFR1 = _BV(ICF1); // Clear the timer flag
  //PORTD |= _BV(2); // Diagnostic pin (D2)
  //dds.clockTick();
  afsk.timer();
  //PORTD &= ~(_BV(2)); // Pin D2 off again
 }
--- a/examples/ChromeHAMShield/background.js
+++ b/examples/ChromeHAMShield/background.js
@ -1,8 +0,0 @@
 chrome.app.runtime.onLaunched.addListener(function() {
  chrome.app.window.create("window.html", {
    "bounds": {
        "width": 685,
        "height": 263
    }
    });
 });
--- a/examples/ChromeHAMShield/manifest.json
+++ b/examples/ChromeHAMShield/manifest.json
@ -1,10 +0,0 @@
 {
  "name": "HamShield",
  "description": "HamShield",
  "version": "1.0.0",
  "app": {
    "background": {
        "scripts": ["background.js"]
    }
  }
 }
--- a/examples/ChromeHAMShield/project.ps
+++ b/examples/ChromeHAMShield/project.ps
@ -1 +0,0 @@
 chromeApp
--- a/examples/ChromeHAMShield/styles.css
+++ b/examples/ChromeHAMShield/styles.css
@ -1,48 +0,0 @@
 body{
  display: inline-block;  
 }
 .btn {
  background: #adadad;
  background-image: -webkit-linear-gradient(top, #adadad, #3d3d3d);
  background-image: -moz-linear-gradient(top, #adadad, #3d3d3d);
  background-image: -ms-linear-gradient(top, #adadad, #3d3d3d);
  background-image: -o-linear-gradient(top, #adadad, #3d3d3d);
  background-image: linear-gradient(to bottom, #adadad, #3d3d3d);
  -webkit-border-radius: 0;
  -moz-border-radius: 0;
  border-radius: 0px;
  font-family: Arial;
  color: #ffffff;
  font-size: 20px;
  padding: 10px 20px 10px 20px;
  text-decoration: none;
  float: left;
  text-align:center;
 }
 .btn:hover {
  background: #3d3d3d;
  text-decoration: none;
 }
 .lcd {
  -webkit-border-radius: 0;
  -moz-border-radius: 0;
  border-radius: 0px;
  font-family: Courier New;
  color: #00ff00;
  font-size: 50px;
  background: #000000;
  padding: 10px 20px 10px 20px;
  text-decoration: none;
  width: 500px;
 }
 .lcd:hover {
  text-decoration: none;
 }
 .bs1 { width: 50px; }
 .bs2 { width: 100px; }
 .bs3 { width: 200px; }
--- a/examples/ChromeHAMShield/window.html
+++ b/examples/ChromeHAMShield/window.html
@ -1,67 +0,0 @@
 <!DOCTYPE html>
 <html>
  <head>
    <link rel="stylesheet" type="text/css" href="styles.css">
  </head>
  <body>
    <div class="lcd" style="width: 623px">
       220.000 MHz
    </div>
    <div class="lcd" style="width: 623px; font-size: 15px;">
      1.25M | BW 12.5KHz | TX CTCSS: 103.5 | RX CTCSS: 109.4 | Filter OFF  
    </div>
    <div class="btn" style="width: 75px">
       BW
    </div>
    <div class="btn">
       Band
    </div>
    <div class="btn">
      +
    </div>
    <div class="btn">
      -
    </div>
    <div class="btn">
      &lt;&lt;
    </div>
    <div class="btn">
      &gt;&gt;
    </div>
    <div class="btn">
      SQ-
    </div>
    <div class="btn">
      SQ+
    </div>
    <div class="btn">
      VOL
    </div>
    <br/>
    <div class="btn">
    CTCSS
    </div>
    <div class="btn">
    CDCSS
    </div>
    <div class="btn">
    Vox
    </div>
    <div class="btn">
    Filter
    </div>
    <div class="btn">
    Offset
    </div>
    <div class="btn">
    Directory
    </div>
    <div class="btn">
    WX
    </div> 
    <br/>
    <div class="btn" style="width: 622px">
      Transmit
    </div>
  </body>
 </html>
--- a/examples/CrystalCalibration/CrystalCalibration.ino
+++ b/examples/CrystalCalibration/CrystalCalibration.ino
@ -1,285 +0,0 @@
 /* Hamshield
 * Example: Crystal Calibration
 * This example allows you to calibrate the crystal clock 
 * through the Arduino Serial Monitor.
 * Connect the HamShield to your Arduino. Screw the antenna 
 * into the HamShield RF jack. Connect the Arduino to wall 
 * power and then to your computer via USB. After uploading 
 * this program to your Arduino, open the Serial Monitor.
 * Make sure drop-down menu at the bottom of Serial Monitor
 * is set to "Newline". Type 'h' into the bar at the top of 
 * the Serial Monitor and click the  "Send" button for more 
 * instructions.
 */
 #define DDS_REFCLK_DEFAULT 38400
 #define DDS_REFCLK_OFFSET  0
 #define DDS_DEBUG_SERIAL
 #include <HamShield.h>
 #include <DDS.h>
 #define PWM_PIN 3
 #define RESET_PIN A3
 #define SWITCH_PIN 2
 HamShield radio;
 DDS dds;
 void setup() {
  // NOTE: if not using PWM out, it should be held low to avoid tx noise
  pinMode(PWM_PIN, OUTPUT);
  digitalWrite(PWM_PIN, LOW);
  // prep the switch
  pinMode(SWITCH_PIN, INPUT_PULLUP);
  // set up the reset control pin
  pinMode(RESET_PIN, OUTPUT);
  // turn on radio
  digitalWrite(RESET_PIN, HIGH);
  delay(5); // wait for device to come up
  Serial.begin(9600);
  radio.initialize();
  radio.setRfPower(0);
  radio.frequency(145050);
  dds.start();
  dds.setFrequency(1200);
  dds.on();
  radio.bypassPreDeEmph();
 }
 enum Sets {
  SET_REF,
  SET_TONE,
  SET_AMPLITUDE,
  SET_ADC_HALF,
  SET_OFFSET
 } setting = SET_TONE;
 char freqBuffer[8];
 char *freqBufferPtr = freqBuffer;
 uint16_t lastFreq = 1200;
 volatile uint16_t recordedPulseLength;
 volatile bool recordedPulse = false;
 volatile bool listening = false;
 volatile uint8_t maxADC = 0, minADC = 255, adcHalf = 40;
 void loop() {
  static uint16_t samples = 0;
  static uint16_t pulse;
  static uint32_t lastOutput = 0;
  static float pulseFloat = 0.0;
  if(recordedPulse) {
    uint32_t pulseAveraging;
    uint16_t tmpPulse;
    cli();
    recordedPulse = false;
    tmpPulse = recordedPulseLength;
    sei();
    if(samples++ == 0) {
      pulse = tmpPulse;
      //pulseFloat = tmpPulse;
    } else {
      pulseAveraging = (pulse + tmpPulse) >> 1;
      pulse = pulseAveraging;
      pulseFloat = pulseFloat + 0.01*((float)pulse-pulseFloat);
    }
    if((lastOutput + 1000) < millis()) {
      Serial.print(F("Pulse:   "));
      Serial.println(pulse);
      Serial.print(F("Last:    "));
      Serial.println(tmpPulse);
      Serial.print(F("Samples: "));
      Serial.println(samples);
      Serial.print(F("ADC M/M: "));
      Serial.print(minADC); minADC = 255;
      Serial.print(F(" / "));
      Serial.println(maxADC); maxADC = 0;
      Serial.print(F("Freq:    "));
      // F = 1/(pulse*(1/ref))
      // F = ref/pulse
      Serial.print((float)((float)dds.getReferenceClock()+(float)dds.getReferenceOffset())/(float)pulse);
      Serial.print(F(" / "));
      Serial.print((float)((float)dds.getReferenceClock()+(float)dds.getReferenceOffset())/pulseFloat);
      Serial.print(F(" / "));
      Serial.println(pulseFloat);
      Serial.print(F("Freq2:   "));
      // F = 1/(pulse*(1/ref))
      // F = ref/pulse
      Serial.print((float)dds.getReferenceClock()/(float)pulse);
      Serial.print(F(" / "));
      Serial.println((float)dds.getReferenceClock()/pulseFloat);
      samples = 0;
      lastOutput = millis();
    }
  }
  while(Serial.available()) {
    char c = Serial.read();
    Serial.println(c);
    switch(c) {
      case 'h':
        Serial.println(F("Commands:"));
        Serial.println(F("RefClk: u = +10, U = +100, r XXXX = XXXX"));
        Serial.println(F("        d = -10, D = -100"));
        Serial.println(F("Offset: s XXX = Set refclk offset"));
        Serial.println(F("Radio:  T = transmit, R = receive"));
        Serial.println(F("Tone:   t XXXX = XXXX Hz"));
        Serial.println(F("Amp.:   a XXX  = XXX out of 255"));
        Serial.println(F("DDS:    o = On, O = Off"));
        Serial.println(F("Input:  l = Determine received frequency, L = stop"));
        Serial.println(F("ADC:    m XXX = Set ADC midpoint (zero crossing level)"));
        Serial.println(F("ie. a 31 = 32/255 amplitude, r38400 sets 38400Hz refclk"));
        Serial.println("> ");
        break;
      case 'u':
        dds.setReferenceClock(dds.getReferenceClock()+10);
        dds.setFrequency(lastFreq);
        dds.start();
        Serial.println(F("RefClk + 10 = "));
        Serial.println(dds.getReferenceClock());
        Serial.println("> ");
        break;
      case 'U':
        dds.setReferenceClock(dds.getReferenceClock()+100);
        dds.setFrequency(lastFreq);
        dds.start();
        Serial.println(F("RefClk + 100 = "));
        Serial.println(dds.getReferenceClock());
        Serial.println("> ");
        break;
      case 'd':
        dds.setReferenceClock(dds.getReferenceClock()-10);
        dds.setFrequency(lastFreq);
        dds.start();
        Serial.println(F("RefClk - 10 = "));
        Serial.println(dds.getReferenceClock());
        Serial.println("> ");
        break;
      case 'D':
        dds.setReferenceClock(dds.getReferenceClock()-100);
        dds.setFrequency(lastFreq);
        dds.start();
        Serial.println(F("RefClk - 100 = "));
        Serial.println(dds.getReferenceClock());
        Serial.println("> ");
        break;
      case 'l':
        Serial.println(F("Start frequency listening, DDS off"));
        dds.off();
        listening = true;
        lastOutput = millis();
        Serial.println("> ");
        break;
      case 'L':
        Serial.println(F("Stop frequency listening, DDS on"));
        listening = false;
        samples = 0;
        dds.on();
        Serial.println("> ");
        break;
      case 'T':
        Serial.println(F("Radio transmit"));
        radio.setModeTransmit();
        Serial.println("> ");
        break;
      case 'R':
        Serial.println(F("Radio receive"));
        radio.setModeReceive();
        Serial.println("> ");
        break;
      case 'r':
        setting = SET_REF;
        break;
      case 't':
        setting = SET_TONE;
        break;
      case 'a':
        setting = SET_AMPLITUDE;
        break;
      case 'm':
        setting = SET_ADC_HALF;
        break;
      case 's':
        setting = SET_OFFSET;
        break;
      case 'o':
        dds.on();
        Serial.println("> ");
        break;
      case 'O':
        dds.off();
        Serial.println("> ");
        break;
      default:
        if(c == '-' || (c >= '0' && c <= '9')) {
          *freqBufferPtr = c;
          freqBufferPtr++;
        }
        if((c == '\n' || c == '\r') && freqBufferPtr != freqBuffer) {
          *freqBufferPtr = '\0';
          freqBufferPtr = freqBuffer;
          uint16_t freq = atoi(freqBuffer);
          if(setting == SET_REF) {
            dds.setReferenceClock(freq);
            dds.setFrequency(lastFreq);
            dds.start();
            Serial.print(F("New Reference Clock: "));
            Serial.println(dds.getReferenceClock());
          } else if(setting == SET_TONE) {
            dds.setFrequency(freq);
            lastFreq = freq;
            Serial.print(F("New Tone: "));
            Serial.println(freq);
          } else if(setting == SET_AMPLITUDE) {
            dds.setAmplitude((uint8_t)(freq&0xFF));
            Serial.print(F("New Amplitude: "));
            Serial.println((uint8_t)(freq&0xFF));
          } else if(setting == SET_ADC_HALF) {
            adcHalf = freq&0xFF;
            Serial.print(F("ADC midpoint set to "));
            Serial.println((uint8_t)(freq&0xFF));
          } else if(setting == SET_OFFSET) {
            dds.setReferenceOffset((int16_t)atoi(freqBuffer));
            dds.setFrequency(lastFreq);
            Serial.print(F("Refclk offset: "));
            Serial.println(dds.getReferenceOffset());
          }
          Serial.println("> ");
        }
        break;
    }
  }
 }
 ISR(ADC_vect) {
  static uint16_t pulseLength = 0;
  static uint8_t lastADC = 127;
  cli();
  TIFR1 = _BV(ICF1);
  //PORTD |= _BV(2);
  dds.clockTick();
  sei();
  if(listening) {
    pulseLength++;
    if(ADCH >= adcHalf && lastADC < adcHalf) {
      // Zero crossing, upward
      recordedPulseLength = pulseLength;
      recordedPulse = true;
      pulseLength = 0;
    }
    if(minADC > ADCH) {
      minADC = ADCH;
    }
    if(maxADC < ADCH) {
      maxADC = ADCH;
    }
    lastADC = ADCH;
  }
  //PORTD &= ~_BV(2);
 }
--- a/examples/FunctionalTest/FunctionalTest.ino
+++ b/examples/FunctionalTest/FunctionalTest.ino
@ -1,82 +0,0 @@
 /* Hamshield
 * Example: Functional Test
 * This is a simple example to demonstrate HamShield receive
 * and transmit functionality.
 * Connect the HamShield to your Arduino. Screw the antenna 
 * into the HamShield RF jack. Plug a pair of headphones into 
 * the HamShield. Connect the Arduino to wall power and then 
 * to your computer via USB. After uploading this program to 
 * your Arduino, open the Serial Monitor. Serial Monitor will 
 * describe what you should be expecting to hear from your 
 * headphones. Tune a HandytTalkie to 446MHz to hear morse 
 * code example.
 */
 #include <HamShield.h>
 #define PWM_PIN 3
 #define RESET_PIN A3
 #define SWITCH_PIN 2
 HamShield radio;
 void setup() {
  // NOTE: if not using PWM out, it should be held low to avoid tx noise
  pinMode(PWM_PIN, OUTPUT);
  digitalWrite(PWM_PIN, LOW);
  // prep the switch
  pinMode(SWITCH_PIN, INPUT_PULLUP);
  // set up the reset control pin
  pinMode(RESET_PIN, OUTPUT);
  digitalWrite(RESET_PIN, HIGH);
  delay(5); // wait for device to come up
  Serial.begin(9600);
  Serial.println("If the sketch freezes at radio status, there is something wrong with power or the shield");
  Serial.print("Radio status: ");
  int result = radio.testConnection();
  Serial.println(result,DEC);
  Serial.println("Setting radio to its defaults..");
  radio.initialize();
 }
 void loop() {
  radio.setModeReceive();
  radio.setSQLoThresh(0);
  radio.setSQOff();
  radio.setVolume1(0xF);
  radio.setVolume2(0xF);
  delay(1000);
  Serial.println("Changing frequency to 446.000 and waiting 10 seconds. You should hear static fading in.");
    radio.frequency(446000);
  for(int x = 0; x < 16; x++) { radio.setVolume1(x); delay(500); Serial.print(x); Serial.print(".."); } 
  for(int x = 0; x < 16; x++) { radio.setVolume2(x); delay(500); Serial.print(x); Serial.print(".."); }   
      radio.setVolume1(0xF);
    radio.setVolume2(0xF);
  delay(10000);
  Serial.println("Changing frequency to 450.000 and waiting 10 seconds. You should hear static.");
  radio.frequency(446000);
  delay(10000);
  Serial.println("Changing frequency to 220.000 and waiting 10 seconds. you should hear static.");
  radio.frequency(220000);
  delay(10000);
  Serial.println("Changing frequency to 144.520 and waiting 10 seconds. you should hear static.");
  radio.frequency(144520);
  delay(10000);
  Serial.println("Now lets scan for a weather radio station and listen for a while....");
  radio.setWXChannel(radio.scanWXChannel());
  Serial.println("If you hear weather radio, it means the scanWXChannel() and setWXChannel() and VHF works.");
  Serial.println("We will sit here for 30 seconds because weather is important.");
  delay(30000);
  Serial.println("We will now tune to 446.000 and send morse code");
  radio.frequency(446000);
  radio.setModeTransmit();
  radio.morseOut("HELLO PERSON");
  radio.setModeReceive();
  Serial.println("Now we are receiving on the call frequency. Starting over again.");
 }
--- a/examples/Gauges/Gauges.ino
+++ b/examples/Gauges/Gauges.ino
@ -1,116 +0,0 @@
 /* Hamshield
 * Example: Gauges
 * This example prints Signal, Audio In, and Audio Rx ADC 
 * Peak strength to the Serial Monitor in a graphical manner.
 * Connect the HamShield to your Arduino. Screw the antenna 
 * into the HamShield RF jack. Plug a pair of headphones into 
 * the HamShield. Connect the Arduino to wall power and then 
 * to your computer via USB. After uploading this program to 
 * your Arduino, open the Serial Monitor. You will see a 
 * repeating display of different signal strengths. Ex: 
 *
 * [....|....] -73       
 * Signal 
 *
 * Uncheck the "Autoscroll" box at the bottom of the Serial 
 * Monitor to manually control the view of the Serial Monitor.
 */
 #include <HamShield.h>
 #define PWM_PIN 3
 #define RESET_PIN A3
 #define SWITCH_PIN 2
 HamShield radio;
 void setup() {
  // NOTE: if not using PWM out, it should be held low to avoid tx noise
  pinMode(PWM_PIN, OUTPUT);
  digitalWrite(PWM_PIN, LOW);
  // prep the switch
  pinMode(SWITCH_PIN, INPUT_PULLUP);
  // set up the reset control pin
  pinMode(RESET_PIN, OUTPUT);
  digitalWrite(RESET_PIN, HIGH);
  delay(5); // wait for device to come up
  analogReference(DEFAULT);
  Serial.begin(9600);
  Serial.print("Radio status: ");
  int result = radio.testConnection();
  Serial.println(result,DEC); 
  radio.initialize();
  radio.frequency(446000);
  radio.setModeReceive();
  Serial.println("Entering gauges...");
  tone(9,1000);
  delay(2000);
 }
 int gauge;
 int x = 0;
 int y = 0;
 int peak = 0;
 int a = 0;
 int mini = 0;
 int vpeak = 0;
 int txc = 0;
 int mode = 0;
 void loop() {
   int16_t rssi = radio.readRSSI();
   gauge = map(rssi,-123,-50,0,8);
   Serial.print("[");
   for(x = 0; x < gauge; x++) { 
     Serial.print(".");
   }
   Serial.print("|");
   for(y = x; y < 8; y++) { 
    Serial.print(".");
   }
   Serial.print("] ");
   Serial.print(rssi);
   Serial.println("       ");
   Serial.println("Signal       \n");
   // radio.setModeTransmit();
   int16_t vssi = radio.readVSSI();
   // radio.setModeReceive();
   if(vssi > vpeak) { vpeak = vssi; } 
   gauge = map(vssi,-50,-150,0,8);
   Serial.print("[");
   for(x = 0; x < gauge; x++) { 
     Serial.print(".");
   }
   Serial.print("|");
   for(y = x; y < 8; y++) { 
    Serial.print(".");
   }
   Serial.print("] ");
   Serial.print(vpeak);
   Serial.println("       ");
   Serial.println("Audio In\n");   
   a = analogRead(0);
   if(a > peak) { peak = a; } 
   if(a < mini) { mini = a; } 
   gauge = map(a,400,1023,0,8);
   Serial.print("[");
   for(x = 0; x < gauge; x++) { 
     Serial.print(".");
   }
   Serial.print("|");
   for(y = x; y < 8; y++) { 
    Serial.print(".");
   }
   Serial.print("] ");
   Serial.print(a,DEC);
   Serial.print(" ("); Serial.print(peak,DEC); Serial.println(")   ");
   Serial.println("Audio RX ADC Peak\n");
 }
--- a/examples/SignalTest/SignalTest.ino
+++ b/examples/SignalTest/SignalTest.ino
@ -1,6 +1,6 @@
 /* Hamshield
 * Example: Signal Test
- * Plays back the current signal strength level and morses out 
+ * Transmits current signal strength level and Morses out 
 * it's call sign at the end. You will need a HandyTalkie (HT)
 * to test the output of this example. You will also need to 
 * download the PCM library from